Rustin R. Lovewell scite author profile

Nitric oxide (NO) contributes to protection from tuberculosis (TB). It is generally assumed that this protection is due to direct inhibition of Mycobacterium tuberculosis (Mtb) growth, which prevents subsequent pathological inflammation. In contrast, we report NO primarily protects mice by repressing an interleukin-1 and 12/15-lipoxygenase dependent neutrophil recruitment cascade that promotes bacterial replication. Using Mtb mutants as indicators of the pathogen's environment, we inferred that granulocytic inflammation generates a nutrient-replete niche that supports Mtb growth. Parallel clinical studies indicate that a similar inflammatory pathway promotes TB in patients. The human 12/15 lipoxygenase ortholog, ALOX12, is expressed in cavitary TB lesions, the abundance of its products correlate with the number of airway neutrophils and bacterial burden, and a genetic polymorphism that increases ALOX12 expression is associated with TB risk. These data suggest that Mtb exploits neutrophilic inflammation to preferentially replicate at sites of tissue damage that promote contagion.

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Pseudomonas aeruginosa Evasion of Phagocytosis Is Mediated by Loss of Swimming Motility and Is Independent of Flagellum Expression

Amiel¹,

Lovewell²,

O’Toole³

et al. 2010

Infect Immun

128

151

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Pseudomonas aeruginosa is a pathogenic Gram-negative bacterium that causes severe opportunistic infections in immunocompromised individuals; in particular, severity of infection with P. aeruginosa positively correlates with poor prognosis in cystic fibrosis (CF) patients. Establishment of chronic infection by this pathogen is associated with downregulation of flagellar expression and of other genes that regulate P. aeruginosa motility. The current paradigm is that loss of flagellar expression enables immune evasion by the bacteria due to loss of engagement by phagocytic receptors that recognize flagellar components and loss of immune activation through flagellin-mediated Toll-like receptor (TLR) signaling. In this work, we employ bacterial and mammalian genetic approaches to demonstrate that loss of motility, not the loss of the flagellum per se, is the critical factor in the development of resistance to phagocytosis by P. aeruginosa. We demonstrate that isogenic P. aeruginosa mutants deficient in flagellar function, but retaining an intact flagellum, are highly resistant to phagocytosis by both murine and human phagocytic cells at levels comparable to those of flagellum-deficient mutants. Furthermore, we show that loss of MyD88 signaling in murine phagocytes does not recapitulate the phagocytic deficit observed for either flagellum-deficient or motility-deficient P. aeruginosa mutants. Our data demonstrate that loss of bacterial motility confers a dramatic resistance to phagocytosis that is independent of both flagellar expression and TLR signaling. These findings provide an explanation for the well-documented observation of nonmotility in clinical P. aeruginosa isolates and for how this phenotype confers upon the bacteria an advantage in the context of immune evasion.Pseudomonas aeruginosa is an opportunistic Gram-negative bacterial pathogen that causes severe infections in immunocompromised patients and in the pulmonary compartment of patients suffering from cystic fibrosis (CF) (13,14). In CF patients, disease severity is positively correlated with colonization by P. aeruginosa and the establishment of chronic infection. As part of the colonization process, the bacteria undergo a number of genetic changes that assist in their ability to survive in the mammalian host and to evade detection and clearance by the immune system (9, 21). One such change that has been phenotypically characterized for P. aeruginosa is loss of flagellar motility (12,17). Furthermore, the loss of flagellar gene expression and motility function is associated with increased bacterial burdens and increased disease severity in CF patients (12,17). While downregulation of flagellar expression has been inferred to confer a survival advantage on P. aeruginosa once it colonizes the host by evasion of both phagocytic receptors and TLR5-driven inflammatory signaling, the exact contribution of flagellum downregulation with respect to successful immune evasion is unclear (5, 17, 18).Nonopsonic phagocytosis of P. aeruginosa by murine and human mac...

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Mechanisms of phagocytosis and host clearance ofPseudomonas aeruginosa

Lovewell

Patankar

Berwin

2014

American Journal of Physiology-Lung Cellular and Molecular Phys

148

127

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domonas aeruginosa is an opportunistic bacterial pathogen responsible for a high incidence of acute and chronic pulmonary infection. These infections are particularly prevalent in patients with chronic obstructive pulmonary disease and cystic fibrosis: much of the morbidity and pathophysiology associated with these diseases is due to a hypersusceptibility to bacterial infection. Innate immunity, primarily through inflammatory cytokine production, cellular recruitment, and phagocytic clearance by neutrophils and macrophages, is the key to endogenous control of P. aeruginosa infection. In this review, we highlight recent advances toward understanding the innate immune response to P. aeruginosa, with a focus on the role of phagocytes in control of P. aeruginosa infection. Specifically, we summarize the cellular and molecular mechanisms of phagocytic recognition and uptake of P. aeruginosa, and how current animal models of P. aeruginosa infection reflect clinical observations in the context of phagocytic clearance of the bacteria. Several notable phenotypic changes to the bacteria are consistently observed during chronic pulmonary infections, including changes to mucoidy and flagellar motility, that likely enable or reflect their ability to persist. These traits are likewise examined in the context of how the bacteria avoid phagocytic clearance, inflammation, and sterilizing immunity.

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Chewing the fat: lipid metabolism and homeostasis during M. tuberculosis infection

Lovewell

Sassetti

VanderVen

2016

Current Opinion in Microbiology

110

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Step-Wise Loss of Bacterial Flagellar Torsion Confers Progressive Phagocytic Evasion

Lovewell¹,

Collins²,

Acker³

et al. 2011

PLoS Pathog

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Phagocytosis of bacteria by innate immune cells is a primary method of bacterial clearance during infection. However, the mechanisms by which the host cell recognizes bacteria and consequentially initiates phagocytosis are largely unclear. Previous studies of the bacterium Pseudomonas aeruginosa have indicated that bacterial flagella and flagellar motility play an important role in colonization of the host and, importantly, that loss of flagellar motility enables phagocytic evasion. Here we use molecular, cellular, and genetic methods to provide the first formal evidence that phagocytic cells recognize bacterial motility rather than flagella and initiate phagocytosis in response to this motility. We demonstrate that deletion of genes coding for the flagellar stator complex, which results in non-swimming bacteria that retain an initial flagellar structure, confers resistance to phagocytic binding and ingestion in several species of the gamma proteobacterial group of Gram-negative bacteria, indicative of a shared strategy for phagocytic evasion. Furthermore, we show for the first time that susceptibility to phagocytosis in swimming bacteria is proportional to mot gene function and, consequently, flagellar rotation since complementary genetically- and biochemically-modulated incremental decreases in flagellar motility result in corresponding and proportional phagocytic evasion. These findings identify that phagocytic cells respond to flagellar movement, which represents a novel mechanism for non-opsonized phagocytic recognition of pathogenic bacteria.

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